Supershear transition mechanism induced by step over geometry

Geophysical Research Letters

2019

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While prior numerical simulations indicate that the Earth's free surface can induce supershear propagation on strike‐slip faults, copious observations of strike‐slip earthquakes have produced only a few instances of such supershear rupture. Our dynamic rupture simulations with varying initial normal stresses and fault strengths show that free‐surface‐induced supershear rupture on strike‐slip faults may return to sub‐Rayleigh speed as the rupture progresses. Such a phenomenon is defined as unsustained free‐surface‐induced supershear rupture, indicating that a rupture on a strike‐slip fault, even if it encounters the free surface, may not generate supershear rupture that is sustained long enough to be observable. The shape of the rupture front contour on the fault may also lead to a false impression about the rupture velocity, since the daughter crack may also propagate at sub‐Rayleigh speed, with near‐field fault‐perpendicular ground motion. Shallower hypocenter depths increase the likelihood of an unsustained free‐surface‐induced supershear rupture.

Section: Introductionmentioning

confidence: 99%

The Sustainability of Free‐Surface‐Induced Supershear Rupture on Strike‐Slip Faults

Oglesby

Geophysical Research Letters

2019

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“…Its simplicity in use and accuracy in predicting dynamic rupture behaviors made it widely used in rupture dynamics (Andrews 1985;Madariaga et al 1998;Zhang and Chen 2006a, b;Hu et al 2014Hu et al , 2016bXu et al 2015). As shown in Eq.…”

Section: Two Different Nucleation Methodsmentioning

confidence: 99%

Effect of the time-weakening friction law during the nucleation process

Huang

2017

Earthq Sci

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Based on dynamic rupture simulations on a planar fault in a homogeneous half-space, we investigated the nucleation processes using the time-weakening friction law. Both the characteristic time and the rupture speed in the nucleation asperity play an important role in determining rupture behaviors on a fault plane following the time-weakening friction law, with which rupture starts from a single point in the nucleation asperity and propagates at a given speed toward the boundary of the nucleation area. Rupture with a small characteristic time or a large rupture speed in the nucleation asperity propagates earlier from the hypocenter. Rupture following the slipweakening friction law requires a smaller radius of nucleation patch to have similar rupture front contours of the time-weakening friction law. Even if the rupture velocity in the nucleation patch of the time-weakening friction law increases to infinity, the peak slip rate in the nucleation asperity is smaller than that of the slip-weakening law. The peak ground velocity distributions of ruptures following the two friction laws are also compared.

“…An “earthquake bright spot,” which represents a localized area that radiates strong high‐frequency seismic waves (Umeda, ), is detected when both the nucleation and the termination of cracks occur in a localized area (Yamashita & Umeda, ). The rupture speed may change significantly when a rupture jumps across fault discontinuities of strike‐slip step overs (Hu, Xu, et al, ; Kase & Kuge, ; Ryan & Oglesby, ). However, the manner in which a rupture speed transition across a step over affects the characteristics of the high‐frequency near‐field ground motion is still unclear.…”

Section: Introductionmentioning

confidence: 99%

“…Although many natural earthquakes propagate at sub‐Rayleigh speeds (Heaton, ), multiple numerical and experimental studies, along with observations of natural earthquakes, have proven the existence of supershear ruptures (Andrews, ; Archuleta, ; Bouchon et al, ; Dunham, ; Dunham et al, ; Harris & Day, ; Huang et al, ; Kaneko & Lapusta, ; Liu & Lapusta, ; Shi & Ben‐Zion, ; Xia et al, ; Xu et al, ; Zhang & Chen, ). In addition, step over geometries are one of the causes of supershear transitions on secondary fault segments because of the barrier effects of the geometrical discontinuity (Hu, Xu, et al, ; Kase & Kuge, ; Ryan & Oglesby, ), although unsustained supershear ruptures are often observed on secondary faults (Hu, Xu, et al, ).…”

Section: Introductionmentioning

confidence: 99%

High Frequency Near‐Field Ground Motion Excited by Strike‐Slip Step Overs

Wen

2018

JGR Solid Earth

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We performed dynamic rupture simulations on step overs with 1–2 km step widths and present their corresponding horizontal peak ground velocity distributions in the near field within different frequency ranges. The rupture speeds on fault segments are determinant in controlling the near‐field ground motion. A Mach wave impact area at the free surface, which can be inferred from the distribution of the ratio of the maximum fault‐strike particle velocity to the maximum fault‐normal particle velocity, is generated in the near field with sustained supershear ruptures on fault segments, and the Mach wave impact area cannot be detected with unsustained supershear ruptures alone. Sub‐Rayleigh ruptures produce stronger ground motions beyond the end of fault segments. The existence of a low‐velocity layer close to the free surface generates large amounts of high‐frequency seismic radiation at step over discontinuities. For near‐vertical step overs, normal stress perturbations on the primary fault caused by dipping structures affect the rupture speed transition, which further determines the distribution of the near‐field ground motion. The presence of an extensional linking fault enhances the near‐field ground motion in the extensional regime. This work helps us understand the characteristics of high‐frequency seismic radiation in the vicinities of step overs and provides useful insights for interpreting the rupture speed distributions derived from the characteristics of near‐field ground motion.